Methods and apparatus for direct communication key establishment

ABSTRACT

A UE, a device and a Direct Communication Element. The UE is configured to establish a UE shared key with a Bootstrapping Server Function (BSF) using a Generic Bootstrapping Architecture (GBA) procedure, to discover the device through a discovery procedure after establishing the UE shared key, and to derive a direct communication key from at least the UE shared key. The device is configured to receive a transaction identifier associated with the UE shared key from the UE, to send the transaction identifier to the Direct Communication Element, and to receive the direct communication key from the Direct Communication Element. The Direct Communication Element is configured to receive the transaction identifier from the device, to obtain a shared session key from the BSF; to derive the direct communication key, and to send the direct communication key to the device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 14/646,779, having a 35 U.S.C. §371 date of May 22, 2015 (published as US 20160345169), which is a 35 U.S.C. §371 National Stage of International Patent Application No. PCT/EP2015/050864, filed Jan. 19, 2015. The above identified applications and publication are incorporated by reference.

TECHNICAL FIELD

The present invention relates to methods for establishing a key for direct communication between a User Equipment device, UE, and a device. The present invention also relates to a UE, a device and a Direct Communication Element, and to a computer program configured to carry out methods for establishing a key for direct communication between a UE and a device.

BACKGROUND

Direct communication involves establishing a radio connection between two devices without transiting via an access network of a cellular communication network. Direct communication may be used to establish communication between two User Equipment Devices (UEs) which may or may not be out of network coverage, or may enable one device to act as a relay for another device, providing access to network services to a device which is out of network coverage. In the 3^(rd) Generation Partnership Project (3GPP), direct communication is enabled via Proximity Services (ProSe), as set out in TS 33.303 and other standard documents. The following discussion focuses on 3GPP ProSe but is equally applicable to other direct communication technologies.

ProSe consists of two main elements: ProSe Direct Discovery, involving the network assisted discovery of users with a desire to communicate who are in close physical proximity, and ProSe Direct Communication, in which direct communication between such users is facilitated with or without supervision from the network. The ProSe direct communication path may use Evolved UMTS Terrestrial Radio Access (E-UTRA) or Wireless Local Area Network direct (WLAN direct) radio technology.

FIG. 1 illustrates a reference ProSe architecture, according to which two ProSe-enabled UEs 2 may establish a direct communication path between them. Communication between the devices takes place over the PC5 interface, with each device able to communicate with a ProSe Function 4 in the cellular network over the PC3 interface, and with a ProSe application server 6 over a PC1 interface. ProSe direct communication may also involve a ProSe “UE-to-Network Relay”, according to which a device, which may itself be a UE, may act as a relay between the E-UTRAN and a UE which is out of the coverage area of the E-UTRAN. This arrangement is illustrated in FIG. 2, with remote UE 2 obtaining access to the E-UTRAN via ProSe direct communication with a ProSe UE-to-Network Relay 8. ProSe direct communication is particularly advantageous for public safety communication, providing communication services for the emergency services and other public safety bodies. The example of FIG. 2 illustrates the ProSe enabled remote UE 2 communicating with a Public Safety Application Server 10 via the E-UTRAN and EPC, which the remote UE 2 can access via ProSe direct communication with the ProSe UE-to-Network Relay 8.

In order to secure communication between two devices using ProSe Direct Communication, a shared key may be used when communicating over the PC5 interface. Standard procedure is to pre-configure appropriate shared keys into ProSe enabled devices. However, pre-configuring appropriate shared keys to enable ProSe Direct Communication with every other device that an enabled device may wish to communicate with may be extremely challenging. A single ProSe enabled UE may wish to communicate with a range of different ProSe enabled UEs, and with many different UE-to-Network Relays serving different cells within the network. In addition, two ProSe enabled UEs, or a UE and UE-to-Network Relay, wishing to communicate may be served by different Home PLMNs, or one or both devices may roam into a new PLMN, further complicating the task of pre-configuring shared keys. Pre-configuring shared keys in all of the relevant ProSe enabled devices to enable all of the possible communication paths that may be desired is therefore an extremely complex process.

SUMMARY

It is an aim of the present invention to provide methods, apparatus and computer readable media which at least partially address one or more of the challenges discussed above.

According to a first aspect of the present invention, there is provided a method, performed by a User Equipment device, UE, for obtaining a key for direct communication with a device over an interface. The method comprises establishing a UE shared key with a Bootstrapping Server Function (BSF) using a Generic Bootstrapping Architecture (GBA) procedure, and receiving from the BSF a transaction identifier associated with the UE shared key. The method further comprises discovering the device through a discovery procedure after receipt of the transaction identifier, sending the transaction identifier and a Direct Communication Element identifier to the device and requesting the device to obtain the direct communication key. The method further comprises deriving a session shared key from at least the UE shared key and a Direct Communication Element identifier and deriving a direct communication key from at least the session shared key and an identifier of the device.

According to examples of the invention, the steps of the above method may be performed in a different order. For example, the transaction identifier and the Direct Communication Element identifier may be sent to the device after deriving the session shared key and direct communication key.

According to examples of the invention, the device may be a UE, a UE-to-Network Relay, or may be a network node.

According to examples of the invention, the direct communication key may be derived using additional inputs to the session shared key and the device identifier, including for example, the UE identifier or other suitable identifiers. In some examples, the direct communication key may be derived using a Key Derivation Function (KDF), and the input parameters may be hashed or otherwise processed before they are used to derive the direct communication key. The KDF can be any standard function such as the KDF defined in 3GPP TS 33.220.

According to examples of the invention, the interface may comprise a Proximity Services, ProSe, interface, and the Direct Communication Element may comprise at least one of a ProSe Function or a ProSe Key Management Server (KMS). The ProSe interface may comprise a PC5 interface.

According to examples of the invention, at least one of the transaction identifier, the Direct Communication Element identifier or the request to obtain the direct communication key may be comprised within a discovery procedure message.

According to examples of the invention, the method may further comprise receiving a discovery message from the device, wherein the discovery message includes the identifier of the device. The discovery message may be a Direct Discovery broadcast according to ProSe Model A or may be a Direct Discovery request message according to ProSe Model B.

According to examples of the invention, the discovery message may further include the Direct Communication Element identifier.

According to examples of the invention, sending the transaction identifier and the Direct Communication Element identifier to the device and requesting the device to obtain the direct communication key may comprise sending a discovery response message responding to the received discovery message.

According to examples of the invention, the method may further comprise receiving a first confirmation message from the device indicating that the device has obtained the direct communication key.

According to examples of the invention, the first confirmation message may comprise a Message Authentication Code, MAC, generated using the direct communication key.

According to examples of the invention, the method may further comprise checking the MAC using the direct communication key, and if the check is successful, sending a second confirmation message to the device.

According to examples of the invention, the method may further comprise generating a MAC using the direct communication key and sending the MAC to the device with the second confirmation message.

According to examples of the invention, if the device comprises a UE-to-Network relay, the method may further comprise conducting the step of establishing a UE shared key with a BSF using a GBA procedure, and receiving from the BSF a transaction identifier associated with the UE shared key, before exiting a coverage area of the communication network with which the UE is communicating.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, the Direct Communication Element may comprise a first sub-Element in the first communication network and a second sub-Element in the second communication network. The first sub-Element may in some examples be a ProSe Function or ProSe KMS in a home PLMN of the UE and the second sub-Element may be a ProSe Function or ProSe KMS in a home PLMN of the device. In some examples, the BSF may be comprised in the first communication network. A UE or device which is comprised within a communication network may for example comprise a UE or device which subscribes to the communication network.

According to another aspect of the present invention, there is provided a method, performed by a device, for obtaining a key for direct communication with a User Equipment device, UE, over an interface. The method comprises discovering the UE through a discovery procedure and receiving from the UE a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key. The method further comprises sending to the Direct Communication Element identified by the Direct Communication Element identifier the transaction identifier and an identifier of the device, and requesting the Direct Communication Element to provide the device with the direct communication key, and receiving the direct communication key from the Direct Communication Element.

According to examples of the invention, the device may be a UE, a UE-to-Network Relay or may be a network node.

According to examples of the invention, the Direct Communication Element may be a functional element hosted on a server or other processing element.

According to examples of the invention, the interface may comprise a Proximity Services, ProSe, interface, and the Direct Communication Element may comprise at least one of a ProSe Function or a ProSe KMS.

According to examples of the invention, at least one of the transaction identifier, the Direct Communication Element identifier or the request to obtain the direct communication key may be comprised within a discovery procedure message.

According to examples of the invention, the method may further comprise sending a discovery message to the UE, wherein the discovery message includes the identifier of the device. According to some examples, the discovery message may be a Direct Discovery broadcast according to ProSe Model A or a Direct Discovery request message according to ProSe Model B.

According to examples of the invention, the discovery message may further include the Direct Communication Element identifier.

According to examples of the invention, receiving from the UE a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key may comprise receiving a discovery response message responding to the sent discovery message.

According to examples of the invention, the method may further comprise sending a first confirmation message to the UE indicating that the device has obtained the direct communication key.

According to examples of the invention, the method may further comprise generating a Message Authentication Code, MAC, using the direct communication key received from the Direct Communication Element, and sending the MAC with the first confirmation message.

According to examples of the invention, the method may further comprise receiving a second confirmation message from the UE.

According to examples of the invention, the method may further comprise comprising receiving a MAC with the second confirmation message.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, the Direct Communication Element may comprise a first sub-Element in the first communication network and a second sub-Element in the second communication network. In some examples, the first sub-Element may be a ProSe Function or ProSe KMS in a home PLMN of the UE and the second sub-Element may be a ProSe Function or ProSe KMS in a home PLMN of the device.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, sending to and receiving from the Direct Communication Element may comprise sending to and receiving from the second sub-Element comprised within the second communication network.

According to another aspect of the present invention, there is provided a method, performed by a Direct Communication Element, for establishing a key for direct communication over an interface between a User Equipment device, UE, and a device. The method comprises receiving from the device a transaction identifier, a device identifier and a request to provide a direct communication key to the device, sending the transaction identifier to a Bootstrapping Server Function (BSF) corresponding to the transaction identifier, and receiving a session shared key from the BSF. The method further comprises deriving the direct communication key from the session shared key and at least the device identifier, and sending the direct communication key to the device.

According to examples of the invention, the device may be a UE, a UE-to-Network Relay, or may be a network node.

According to examples of the invention, the direct communication key may be derived using additional inputs to the session shared key and the device identifier, including for example, the UE identifier or other suitable identifiers. In some examples, the direct communication key may be derived using a Key Derivation Function (KDF), and the input parameters may be hashed or otherwise processed before they are used to derive the direct communication key. The KDF may be any standard function such as the KDF defined in 3GPP TS 33.220.

According to examples of the invention, the interface may comprise a Proximity Services, ProSe, interface, and the Direct Communication Element may comprise at least one of a ProSe Function or a ProSe KMS.

According to examples of the invention, the method may further comprise checking that the device is authorised to establish direct communication with the UE and/or that the UE is authorised to establish direct communication with the device.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, the Direct Communication Element may comprise a first sub-Element in the first communication network and a second sub-Element in the second communication network. In some examples, the first sub-Element may be a ProSe Function or ProSe KMS in a home PLMN of the UE and the second sub-Element may be a ProSe Function or ProSe KMS in a home PLMN of the device.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, sending to and receiving from at least one of the BSF or the device may comprise sending to and receiving from one of the first or second sub-Elements via the other of the first or second sub-Elements. In some examples, in which the sub-Elements comprise ProSe Functions in different PLMNs, the communication between sub-Elements may be over a PC6 interface.

According to examples of the invention, if the UE is comprised within a first communication network and the device is comprised within a second communication network, sending to and receiving from the BSF may comprise sending and receiving at the first sub-Element, and deriving the direct communication key may comprise deriving the direct communication key at the second sub-Element.

According to another aspect of the present invention, there is provided a computer program configured, when run on a computer, to carry out a method according to any one of the preceding aspects of the present invention.

According to another aspect of the present invention, there is provided a computer program product comprising computer readable medium and a computer program according to the preceding aspect of the present invention stored on the computer readable medium.

According to another aspect of the present invention, there is provided a system for securing direct communication between a User Equipment device, UE, and a device over an interface, the system comprising a UE, a device and a Direct Communication Element. The UE is configured to establish a UE shared key with a Bootstrapping Server Function (BSF) using a Generic Bootstrapping Architecture (GBA) procedure; to discover the device through a discovery procedure after establishing the UE shared key; and to derive a direct communication key from at least the UE shared key. The device is configured to receive a transaction identifier associated with the UE shared key from the UE; to send the transaction identifier to the Direct Communication Element; and to receive the direct communication key from the Direct Communication Element. The Direct Communication Element is configured to receive the transaction identifier from the device, to obtain a shared session key from the BSF; to derive the direct communication key; and to send the direct communication key to the device.

According to some examples of the invention, the UE may be configured to derive the direct communication key by deriving the shared session key from at least the UE shared key and a Direct Communication Element identifier, and by deriving the direct communication key from at least the shared session key and a device identifier.

According to some examples of the invention, the Direct Communication Element may be configured to derive the direct communication key from at least the shared session key and a device identifier.

According to some examples of the invention, the interface may comprise a Proximity Services, ProSe, interface, and the Direct Communication Element may comprise at least one of a ProSe Function or a ProSe KMS.

According to another aspect of the present invention, there is provided a User Equipment device, UE, configured for obtaining a key for direct communication with a device over an interface, the UE comprising a processor and a memory, the memory containing instructions executable by the processor, such that the UE is operable to carry out a method according to the first aspect of the present invention.

According to another aspect of the present invention, there is provided a device configured for obtaining a key for direct communication with a User Equipment device, UE, over an interface, the device comprising a processor and a memory, the memory containing instructions executable by the processor, such that the device is operable to carry out a method according to the second aspect of the present invention.

According to another aspect of the present invention, there is provided a Direct Communication Element configured for establishing a key for direct communication over an interface between a User Equipment device, UE, and a device, the Direct Communication Element comprising a processor and a memory, the memory containing instructions executable by the processor, such that the Direct Communication Element is operable to carry out a method according to the third aspect of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, and to show more clearly how it may be carried into effect, reference will now be made, by way of example, to the following drawings in which:

FIG. 1 is a schematic representation of a Proximity Services (ProSe) architecture;

FIG. 2 is a representation of ProSe including a UE-to-Network Relay;

FIG. 3 is a schematic representation of a Generic Bootstrapping Architecture (GBA);

FIG. 4 is a flow chart illustrating process steps in a method performed by a UE for obtaining a key for direct communication with a device over an interface;

FIG. 5 is a flow chart illustrating process steps in a method performed by a device for obtaining a key for direct communication with a UE over an interface;

FIG. 6 is a flow chart illustrating process steps in a method performed by a Direct Communication Element for establishing a key for direct communication over an interface between a UE and a device;

FIG. 7 is a schematic representation of a system for securing direct communication between a User Equipment device, UE, and a device over an interface;

FIG. 8 is a representation of an example architecture for conducting the methods of FIGS. 4 to 6;

FIG. 9 is a representation of an example architecture for conducting the methods of FIGS. 4 to 6 over ProSe;

FIG. 10 is a message flow illustrating an example implementation of the methods of FIGS. 4 to 6 over ProSe;

FIG. 11 is a representation of another example architecture for conducting the methods of FIGS. 4 to 6 over ProSe, wherein the UE and the device are comprised within different communication networks;

FIG. 12 is a representation of another example architecture for conducting the methods of FIGS. 4 to 6, wherein the UE and the device are comprised within different communication networks;

FIG. 13 is a message flow illustrating an example implementation of the methods of FIGS. 4 to 6 over ProSe;

FIG. 14 is a block diagram illustrating a UE;

FIG. 15 is a block diagram illustrating a device;

FIG. 16 is a block diagram illustrating a Direct Communication Element;

FIG. 17 is a block diagram illustrating another example of a UE;

FIG. 18 is a block diagram illustrating another example of a device;

FIG. 19 is a block diagram illustrating another example of a Direct Communication Element;

FIG. 20 is a block diagram illustrating another example of a UE;

FIG. 21 is a block diagram illustrating another example of a device; and

FIG. 22 is a block diagram illustrating another example of a Direct Communication Element.

DETAILED DESCRIPTION

Aspects of the present invention provide methods enabling the establishment of a Direct Communication Key for securing communication between a UE and a device, which may itself be a UE or may be a UE-to-Network Relay. Aspects of the invention make use of the Generic Bootstrapping Architecture (GBA) in 3GPP networks to assist in the establishing of the Direct Communication key.

FIG. 3 illustrates a reference GBA architecture. GBA is a framework which uses network operator controlled credentials, such as 3GPP Authentication and Key Agreement (AKA) credentials, in the Universal Integrated Circuit Card (UICC) of devices to provide keys for application security. The reference GBA architecture comprises a UE 20, a Bootstrapping Server Function (BSF) 12, a Network Application Function (NAF) 14, a Home Subscription Server (HSS) 16 and a Subscriber Location Function (SLF) 18. Exchanges between the BSF 12 and UE 20 through the reference point Ub enable the establishing of key material Ks in both the BSF 12 and UE 20. The BSF 12 and UE 20 may then each independently generate a NAF specific key, for example a Ks_NAF, which will be used to secure the reference point Ua between the UE 20 and the NAF 14. Ks_NAF is generated using a Key Derivation Function (KDF) with inputs including the key material Ks, the IMPI of the UE 20 and an identification of the NAF 14. The BSF 12 supplies the UE with a Bootstrapping Transaction Identifier (B-TID) corresponding to the exchange as well as a lifetime of the key material Ks. The UE 20 may then supply the B-TID to the NAF 14, enabling the NAF 14 to request the key corresponding to the B-TID from the BSF 12. In response to the request, the BSF 12 supplies Ks_NAF to the NAF 14, meaning the UE 20 and NAF 14 may communicate securely through the reference point Ua using Ks_NAF.

Aspects of the present invention employ the reference GBA architecture, with enhanced functionality in the element operating as a NAF, to establish a shared key between a UE and a device that may be used over a direct communication interface such as a ProSe PC5 interface. In brief, a UE acting according to examples of the present invention initiates GBA bootstrapping with a BSF. Following GBA bootstrapping, a UE shared key Ks is present in both the UE and the BSF. The UE then discovers a device with which it wishes to communicate directly. The UE contacts the discovered device for direct communication and furnishes the B-TID received from the BSF during initial bootstrapping along with an identifier of a Direct Communication Element (DCE) which is to act as a NAF. The device contacts the identified DCE and provides the received B-TID as well as its own identification. The DCE retrieves a session shared key, for example a Ks_NAF, Ks_int_NAF or Ks_ext_NAF, from the BSF using the B-TID and derives a direct communication key K_DC from the session shared key and the identity of the device. The DC key is thus unique both to the UE and the device for direct communication. Additional inputs and/or processing may be used in deriving the direct communication key K_DC. The DCE then provides the direct communication key K_DC to the device. The UE derives the session shared key from the UE shared key Ks and additionally derives the direct communication key K_DC from the session shared key and an identity of the device in the same manner as the NAF. The identity of the device may be provided to the UE by the device in a message and/or may be obtained by the UE during discovery. Both UE and device are then in possession of the direct communication key K_DC to secure communication between them over a direct communication interface. The DCE acting as a NAF in the provisioning of the direct communication key may be a ProSe Function or ProSe KMS operated by a 3GPP network operator. Alternatively, the DCE could be operated by a third party including for example a National Security or Public Safety organisation having an agreement with the 3GPP operator running the BSF.

FIGS. 4 to 6 illustrate methods according to aspects of the present invention performed in each of the UE, the device and the Direct Communication Element. Actions at each entity are described below with reference to FIGS. 4 to 6.

FIG. 4 illustrates steps in a method 100 carried out at a UE for obtaining a key for direct communication with a device, which device may be another UE or may be a UE-to-Network Relay. Referring to FIG. 4, in a first step 102, the UE establishes a UE shared key Ks with a BSF using a GBA procedure, and receives from the BSF a transaction identifier associated with the UE shared key. The UE then discovers the device through a discovery procedure in step 106 after receipt of the transaction identifier. The discovery procedure may be initiated by the device or by the UE. It will be appreciated that a period of time may elapse between the establishing of the UE shared key Ks and the discovery of the device, within which time the UE may for example move out of a network coverage area. The UE sends the transaction identifier and a Direct Communication Element identifier to the device and requests the device to obtain the direct communication key in step 108. The UE derives a session shared key from at least the UE shared key Ks and a Direct Communication Element identifier in step 134. The session shared key may for example be a Ks_NAF, Ks_int_NAF or Ks_ext_NAF. The UE then derives a direct communication key K_DC from at least the session shared key and an identifier of the device in step 136. The identity of the device may be provided to the UE by the device in a message and/or may be obtained by the UE during discovery.

FIG. 5 illustrates steps in a method 200 performed by a device for obtaining a key for direct communication with a UE. The device may be a UE, a UE-to-Network Relay, or may be network node. Referring to FIG. 5, in a first step 204, the device discovers the UE through a discovery procedure, which procedure may be initiated by the device or by the UE. In step 210, the device receives from the UE a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key. The device then sends the transaction identifier and an identifier of the device to the Direct Communication Element identified by the Direct Communication Element identifier, and requests the Direct Communication Element to provide the device with the direct communication key in step 212. The Direct Communication Element may for example be a ProSe Function or a ProSe KMS. Finally, the device receives the direct communication key from the Direct Communication Element in step 226.

FIG. 6 illustrates steps in a method 300 performed by a Direct Communication Element (DCE) for establishing a key for direct communication over an interface between a UE and a device. The DCE may be a ProSe Function or a ProSe KMS, and the device may be a UE, a UE-to-Network Relay, or a Network node. Referring to FIG. 6, in a first step 314, the DCE receives from the device a transaction identifier, a device identifier and a request to provide a direct communication key K_DC to the device. The DCE then sends the transaction identifier to a BSF corresponding to the transaction identifier in step 318 and receives a session shared key from the BSF in step 320. The session shared key may be a Ks_NAF, Ks_int_NAF or Ks_ext_NAF. The DCE then derives the direct communication key K_DC from the session shared key and at least the device identifier in step 322 and finally sends the direct communication key to the device in step 324.

The step of deriving the direct communication key, performed in the UE according to method 100 and in the DCE according to method 300, may be achieved in a range of different ways. In some examples, the direct communication key may be derived using a Key Derivation Function (KDF), which may be any standard function such as the KDF defined in 3GPP TS 33.220. Additional parameters to the session shared key and the device ID mentioned above may be input to the KDF. Example additional input parameters include B-TID, NAF-ID, KMS-ID, ProSe UE-ID, CK∥IK and other inputs. The order of the input parameters may also be varied. The selection of additional parameters and the variation in their order may in some examples result in a more secure generation function. In addition, the input parameters may be transformed, hashed or otherwise processed before they are input to the KDF to derive the direct communication key. For example, a Ks_NAF could be transformed by first being run through another (or the same) key derivation function and the result input to the KDF, or another character sting could be used as input. In the following description, references to the derivation of a direct communication key include the above disclosed options for additional inputs and KDFs.

The above described methods 100, 200, 300 may be performed by elements cooperating to form a system for securing direct communication between a UE and a device over an interface. Such a system is illustrated in FIG. 7 and comprises a UE 20, a device 30 and a Direct Communication Element 40. The UE is configured to establish a UE shared key Ks with a BSF 50 using a GBA procedure and to discover the device 30 through a discovery procedure after establishing the UE shared key. The UE is further configured to derive a direct communication key from at least the UE shared key. The device 30 is configured to receive a transaction identifier associated with the UE shared key from the UE 20, to send the transaction identifier to the DCE 40 and to receive the direct communication key from the DCE 40. The DCE 40 is configured to receive the transaction identifier from the device 30, to obtain a shared session key from the BSF 50, to derive the direct communication key, and to send the direct communication key to the device 30.

The following discussion illustrates further examples of the invention with reference to ProSe communication as supported by a 3GPP network. However it will be appreciated that the invention is equally applicable to other direct communication technologies.

As discussed above, the device 30, at which the method 200 is performed, may be a UE or a UE-to-Network Relay. Both of these options for the device are discussed in the following examples. When discussing an example in which the device is a UE, the UE is referred to as “UE-A” and the device is referred to as “UE-B”. When discussing an example in which the device is a UE-to-Network Relay, the UE is referred to as “Remote UE” and the device is referred to as “UE-to-NW Relay”. It will be appreciated that the example cases are merely for illustration, and method steps performed at UE-A may be mapped to those performed at the Remote UE, and similarly the method steps performed at UE-B may be mapped to the method steps performed at the UE-to-NW Relay. In either case it is assumed that both the UE and the device have a UICC and are enabled for ProSe. The UE may be served by the E-UTRAN throughout the performance of the method 100 or may move out of contact with the E-UTRAN following completion of the initial bootstrapping procedure. This is particularly likely in the case of a device which is a UE-to-Network Relay, as it is likely that any UE within the coverage area of a UE-to-Network Relay will have left the coverage area of the E-UTRAN.

Regardless of the nature of the device, it is possible that the UE and device may be belong to the same Home PLMN or may be belong to different Home PLMNs. Example applications of methods according to the present invention are described below for both these scenarios. The following example applications illustrate different ways in which the steps of the methods 100, 200, 300 described above may be implemented to achieve the above discussed functionality.

EXAMPLE i UE and Device in Same HPLMN

The GBA and ProSe architecture for this example are illustrated in FIGS. 8 and 9. According to this example, the UE, referred to as UE-A (Remote UE) 20 i, and the device, referred to as UE-B (UE-to-NW Relay) 30 i, are both served by the E-UTRAN in the same HPLMN. UE-A (Remote UE) 20 i initiates GBA bootstrapping with the BSF 50 i according to TS 33.220. UE-A (Remote UE) 20 i retrieves a B-TID from the BSF 50 i. Initial bootstrapping takes place with UE-A (Remote UE) 20 i in E-UTRAN coverage but subsequent steps may take place with UE-A (Remote UE) 20 i out of E-UTRAN coverage, for example if UE-B 30 i is acting as a relay or is in fact a UE-to-NW relay 30 i.

UE-B (UE-to-NW Relay) 30 i is using ProSe Direct Discovery procedures to allow UEs in the vicinity to discover it. UE-A (Remote UE) 20 i discovers UE-B (UE-to-NW Relay) 30 i using ProSe Direct Discovery procedures on PC5 interface, for example having moved into the cell in which UE-B (UE-to-NW Relay) 30 i is located. UE-A (Remote UE) 20 i contacts UE-B (UE-to-NW Relay) via the PC5 interface indicating the B-TID and an identity of the DCE 40 i, which in this case is the Home ProSe Function of the PLMN, which is acting as a NAF for the purposes of GBA. UE-A (Remote UE) 20 i may also provide its identity, for example if this has not already been provided via discovery. UE-A (Remote UE) 20 i requests UE-B (UE-to-NW Relay) 30 i to contact the NAF 40 i to request the NAF 40 i to derive the ProSe key for direct communication from a session shared key identified by the B-TID and UE-B (UE-to-NW Relay) 30 i identity. UE-A (Remote UE) 20 i also requests that the derived ProSe key be provisioned to UE-B (UE-to-NW Relay) 30 i. The session shared key is referred to in the present and following examples as a Ks_NAF for the purposes of illustration. However it will be appreciated that the session shared key may also or alternatively comprise other NAF specific keys such as Ks_int_NAF and Ks_ext_NAF.

UE-B (UE-to-Network Relay) then contacts the NAF 40 i with the B-TID and UE-B (UE-to-NW Relay) 30 i identity. If the NAF 40 i does not have the Ks_NAF key identified by the B-TID already, then the NAF 40 i contacts the BSF 50 i with the B-TID and retrieves the corresponding Ks_NAF key. The NAF 40 i derives a ProSe key Ks_UE-B (Ks_UE-to-NW Relay), to be used for direct communication, from the Ks_NAF and UE-B (UE-to-NW Relay) 30 i identity. The NAF 40 i provides the derived ProSe key to UE-B (UE-to-NW Relay) 30 i over a secure link.

UE-A (Remote UE) 20 i derives the shared session key Ks_NAF from its initial bootstrapping procedures and then derives the direct communication ProSe key Ks_UE-B (Ks_UE-to-NW Relay) from Ks_NAF and the UE-B (UE-to-NW Relay) 30 i identity. This identity may be obtained during the discovery procedure or may be received with a confirmation message from the UE-B (UE-to-Network Relay). The ProSe key Ks_UE-B (Ks_UE-to-NW Relay) is then available in UE-A (Remote UE) 20 i for direct communication between UE-A (Remote UE) 20 i and UE-B (UE-t-Network Relay) 30 i on the PC5 interface.

The above steps are described in greater detail below with reference to the messaging flow diagram in FIG. 10.

In step 102 i (message exchanges 1 to 4) UE-A (Remote UE) 20 i is served by E-UTRAN and initiates a GBA bootstrapping with the BSF 50 i according to TS 33.220. When the GBA bootstrapping procedure has taken place successfully then the UE-A (Remote UE) 20 i and the BSF 50 i have established a UE shared key Ks, a B-TID and a key lifetime of the Ks.

Following step 102 i, UE-A (Remote UE) 20 i may move outside of E-UTRAN coverage. In message exchange 5, UE-B (UE-to-NW Relay) 30 i is served by E-UTRAN and initiates E-UTRAN Attach and requests PDN connectivity.

UE-A (Remote UE) 20 i and UE-B (UE-to-NW Relay) 30 i then discover each other through Direct Discovery procedures using Direct Discovery Model A or Direct Discovery Model B at message exchange 6. Discovery may be initiated by either UE-A (Remote UE) 20 i or UE-B (UE-to-NW Relay) 30 i. In the illustrated example, discovery is initiated by UE-B (UE-to-NW Relay) 30 i. In step 204 i, UE-B (UE-to-NW Relay) 30 i issues a discovery message, which may be a Direct Discovery broadcast according to ProSe Model A or a Direct Discovery request message according to ProSe Model B. UE-A (Remote UE) 20 i receives the discovery message at step 106 i. UE-A (Remote UE) 20 i may respond to the Direct Discovery request message according to ProSe Model B or may issue a request message in response to a Direct Discovery broadcast according to ProSe Model A.

In the procedure illustrated at message exchange 8, UE-A (Remote UE) 20 i requests UE-B (UE-to-NW Relay) 30 i to contact the NAF 40 i in order to request the NAF 40 i to derive the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay), to be used for direct communication on the PC5 interface. The ProSe key is to be derived from a Ks_NAF identified by a B-TID sent by UE-A (Remote UE). UE-A (Remote UE) 20 i sends the request to UE-B (UE-to-NW Relay) 30 i on the PC5 interface in step 108 i. The request contains the B-TID and the NAF_ID and is received by UE-B (UE-to-NW Relay) 30 i in step 210 i. The request may also contain the UE-A (Remote UE) 20 i identity, for example if this has not already been provided during discovery.

In message exchange 9, UE-B (ProSe UE-to-Network Relay) 30 i contacts the NAF 40 i over the interface PC3 by initiating the establishment of a secure link with the NAF 40 i. This may comprise initiating, for example, a TLS tunnel using pre-shared certificates or with GBA.

In message exchange 10, UE-B (ProSe UE-to-Network Relay) 30 i requests the NAF 40 i to derive the ProSe key from a Ks_NAF identified by a B-TID, and to provision the derived ProSe key to the UE-B (ProSe UE-to-Network Relay) 30 i. UE-B (ProSe UE-to-Network Relay) 30 i sends the message at step 212 i, including the B-TID received from UE-A (Remote UE) 20 i and the UE-B identity (UE-to-NW Relay identity). The request may also contain the UE-A (Remote UE) 20 i identity. This message is received by the NAF 40 i at step 314 i. In step 316 i (message exchange 11), the NAF 40 i authorizes the UE-B identity (UE-to-NW Relay identity) by checking a database with a list of authorized identities. This database may be local and supported by the NAF 40 i or may be implemented in a different network server. The NAF 40 i may also authorize the UE-A (Remote UE) 20 i identity by checking the database.

If the UE-B identity (UE-to-NW Relay identity), and UE-A (Remote UE) 20 i identity if checked, are configured in the database, then the UE-B (UE-to-NW Relay) 30 i and UE-A (Remote UE) 20 i are authorized to establish direct communication, and the UE-B (UE-to-NW Relay) 30 i is authorized to request the key corresponding to the B-TID. The NAF 40 i therefore contacts the BSF 50 i in step 318 i to request the session shared key Ks_NAF, as described in TS 33.220, and receives Ks_NAF from the BSF 50 i in step 320 i.

In step 322 i (message exchange 12) the NAF 40 i calculates a ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) to be provisioned to UE-B (-UE-to-NW Relay) 30 i. This is the ProSe key for direct communication on the PC5 interface between UE-A (Remote UE) 20 i and UE-B (UE-to-NW Relay) 30 i.

The NAF 40 i calculates the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) from Ks_NAF and UE-B ID (ProSe UE-to-Network Relay ID) as follows:

Ks_UE-B(Ks_UE-to-NW_Relay)=KDF(Ks_NAF, UE-B ID (UE-to-NW Relay ID), . . . ),

where KDF is a key derivation function having as inputs at least Ks_NAF and UE-B ID (UE-to-NW Relay ID). Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place.

The NAF 40 i also generates a ProSe key identity and a ProSe key lifetime to be associated with the newly derived ProSe key Ks_UE-B (Ks_UE-to-NW_Relay).

In message exchange 13, the NAF 40 i sends or provisions the derived key Ks_UE-B (Ks_UE-to-NW_Relay) to UE-B (UE-to-NW Relay) 30 i. NAF 40 i sends a message containing the ProSe key, ProSe key identity and a ProSe key lifetime in step 324 i, which message is received by UE-B (UE-to-NW Relay) 30 i in step 226 i.

In step 228 i, the UE-B (UE-to-NW Relay) 30 i generates a MAC using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) received from the NAF 40 i. The UE-B (UE-to-NW Relay) 30 i then sends a response message to UE-A (Remote UE) 20 i including the UE-B ID (UE-to-NW Relay ID), NAF_ID, ProSe key ID, Lifetime of ProSe key and MAC. The response message is protected with a MAC which is generated using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) and is calculated over the response message. The message is sent by the UE-B (UE-to-NW Relay) 30 i in step 230 i and received by the UE-A (Remote UE) 20 i in step 132 i.

In the procedure illustrated at message exchange X, UE-A (Remote UE) 20 i derives the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) which has been provisioned to the UE-B (UE-to-Network Relay) 30 i by the NAF 40 i. This process is achieved in steps 134 i and 136 i in UE-A (Remote UE) 20 i. In step 134 i, UE-A (Remote UE) calculates the shared session key Ks_NAF from Ks and the NAF_ID as follows:

Ks_NAF=KDF(Ks, NAF_ID, . . . ),

where KDF is a key derivation function having as inputs at least Ks and NAF_ID. Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place. The UE-A (Remote UE) 20 i may already have been in possession of the NAF-ID or may have obtained the NAF ID, as part of discovery procedures before receiving the NAF ID in the message from the UE-B (UE-to-Network Relay) 30 i at step 132 i.

In step 136 i, UE-A (Remote UE) 20 i calculates the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) from Ks_NAF and the UE-B ID (UE-to-NW Relay ID) as follows:

Ks_UE-B(Ks_UE-to-NW_Relay)=KDF(Ks_NAF, UE-B ID(UE-to-NW Relay ID), . . . ).

As discussed above, KDF is a key derivation function having as inputs at least Ks_NAF and UE-B ID (UE-to-NW Relay ID). Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place.

In step 138 i, UE-A (Remote UE) 20 i checks the MAC received from the UE-B (UE-to-NW Relay) 30 i in step 132 i using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay). If the check is successful, then UE-A (Remote UE) 20 i knows that UE-B (UE-to-NW Relay) 30 i shares the same ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) as UE-A (Remote UE) 20 i. UE-A (Remote UE) 20 i can now use the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) for direct communication on the PC5 interface with UE-B (UE-to-NW Relay) 30 i.

In message exchange 15, UE-A (Remote UE) 20 i confirms to UE-B (UE-to-NW Relay) 30 i, that the check of the MAC was successful and that ProSe Direct Communication on PC5 interface between UE-A (Remote UE) 20 i and UE-B (UE-to-NW Relay) 30 i can now take place using the derived ProSe key Ks_UE-B (Ks_UE-to-NW_Relay). In some examples, a further derivation step may be applied to the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) before it is used. UE-A (Remote UE) 20 i protects the confirmation with a MAC using Ks_UE-B (Ks_UE-to-NW_Relay). The confirmation message is sent by UE-A (Remote UE) 20 i in step 140 i and received at UE-B (UE-to-NW Relay) 30 i in step 242 i. The UE-B (UE-to-NW Relay) 30 i then checks the MAC in step 244 i (message exchange 16).

Mutual authentication may be included in the methods illustrated by the above described example in the following manner. UE-A (Remote UE) 20 i and UE-B (UE-to-NW Relay) 30 i may generate nonces for mutual authentication: UE-A (Remote UE) 20 i generates nonce-UE-A and UE-B (UE-to-NW Relay) generates nonce-UE-B. A nonce may for example be a sequence number, a random value or a timestamp. Nonces may be exchanged in various messages of the above described example procedure. In one example, UE-A (Remote UE) 20 i sends nonce-UE-A to UE-B (UE-to-NW Relay) 30 i with the request to obtain a direct communication key sent in step 108 i (message exchange 8). UE-B (UE-to-NW Relay) 30 i takes nonce-UE-A as an input to its calculation of a MAC at step 228 i, which MAC is sent to UE-A (Remote UE) 20 i in step 230 i. When UE-A (Remote UE) 20 i verifies the MAC, this in practice means that UE-A (Remote UE) 20 i authenticates UE-B (UE-to-NW Relay). An equivalent process allows authentication in the other direction. UE-B (UE-to-NW Relay) 30 i sends nonce-UE-B to UE-A (Remote UE) 20 i in step 230 i (message exchange 14). UE-A (Remote UE) uses nonce-UE-B as an input to its MAC calculation, which MAC is sent to the UE-B (UE-to-NW Relay) in step 140 i (message exchange 15). When UE-B (UE-to-NW Relay) 30 i verifies the MAC, this in practice means that UE-B (UE-to-NW Relay) authenticates UE-A (Remote UE) 20 i.

In alternative embodiments, of the above example, the UE-A (Remote UE) 20 i may derive the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) at an earlier stage, for example if the UE-A (Remote UE) 20 i has obtained the NAF-ID and the UE-B ID (UE-to-NW Relay ID) for example during the discovery. The UE-A (Remote UE) 20 i may also already be in possession of the NAF ID. In addition, certain of the exchanges according to aspects of the invention may be combined with the discovery process. Each of these possibilities is described in full in the context of Example iii below.

EXAMPLES ii AND iii UE and Device in Different HPLMNs

In examples in which the UE 20 and device 30 belong to different Home PLMNs, two scenarios may be envisaged: (1) The DCE of the device acts as NAF for GBA bootstrapping; and (2) The DCE of the UE acts as NAF for GBA bootstrapping

In each scenario, the DCE may be the ProSe function of the relevant PLMN or may for example be a KMS of the relevant PLMN. In the following examples, the DCE is a ProSe function, but it will be appreciated that this is merely for the purposes of illustration. In some examples, the DCE may comprise a ProSe Function or KMS in each of the PLMNs, each Function or server acting as a sub-Element of the Direct Communication Element. For example, a ProSe Function in the UE PLMN may act as a NAF for the bootstrapping procedure, as a first sub-Element, with a ProSe Function in the device PLMN deriving the direct communication key, as a second sub-Element. However, only one DCE sub-Element acts as a NAF for the purposes of GBA bootstrapping at any one time.

The ProSe architecture for Examples ii and iii is illustrated in FIG. 11. The PLMN of the UE 20 (UE-A or Remote UE) is designated as PLMN A, with BSF 50A and ProSe Function 40A, which acts as NAF 40A according to option 2 (Example iii). The PLMN of the device 30 (UE-B or UE-to-NW Relay) is designated as PLMN B, with ProSe Function 40B, which acts as NAF 40B according to option 1 (Example ii). According to option 1 (dotted line), the Home ProSe Function of PLMN B, which acts as NAF 40B is the DCE conducting the steps of method 3. According to option 2 (dashed line), the DCE comprises two sub-Elements: the Home ProSe Function 40A of PLMN A, which acts as NAF 40A, and the Home ProSe Function 40B of PLMN B, which acts as a relay and derives the direct communication key. The BSF of PLMN B is not involved in the following examples, as the initial bootstrapping performed by the UE 20 is performed with the BSF of its Home PLMN, BSF 50A.

EXAMPLE ii UE and Device in Different HPLMNs and ProSe Function of the Device Acts as NAF

This example is very similar to Example i described above. The procedure for Example ii is the same as that described with reference to FIG. 10 for Example i with the following differences (equivalent step numbering is used to that of Example i, with the suffix ii applied to refer to steps conducted according to Example ii).

In step 212 ii, UE-B (UE-to-Network Relay) 30 ii contacts its Home ProSe Function, which is acting as the NAF 40Bii. In contrast to Example i, this is not also the Home ProSe Function of UE-A (Remote UE) 20 ii, as UE-A (Remote UE) 20 ii and UE-B (UE-to-Network Relay) 30 ii are comprised within different PLMNs. The NAF 40Bii then contacts the BSF 50Aii of the Home PLMN of UE-A (Remote UE) 20 ii in order to obtain Ks_NAF. This contact may be direct, or the NAF 40Bii may contact the BSF 50Aii using the ProSe Function 40Aii as a proxy or relay to convey messages.

EXAMPLE iii UE and Device in Different HPLMNs and ProSe Function of the UE Acts as NAF

The GBA architecture for this example is illustrated in FIG. 12. According to this example, the UE, referred to as UE-A (Remote UE) 20 iii, and the device, referred to as UE-B (UE-to-NW Relay) 30 iii, are again served by E-UTRAN but by different HPLMNs. UE-A (Remote UE) 20 iii is served by a different Home 3GPP operator to UE-B (UE-to-NW Relay) 30 iii.

UE-A (Remote UE) 20 iii initiates GBA bootstrapping with the BSF 50Aiii in its HPLMN A according to TS 33.220. UE-A (Remote UE) 20 ii retrieves a B-TID from the BSF 50Aiii. Initial bootstrapping takes place with UE-A (Remote UE) 20 iii in E-UTRAN coverage but subsequent steps may take place with UE-A (Remote UE) 20 iii out of E-UTRAN coverage, for example if UE-B 30 iii is acting as a relay or is in fact a UE-to-NW relay 30 iii.

UE-B (UE-to-NW Relay) 30 iii is using ProSe Direct Discovery procedures to allow UEs in the vicinity to discover it. UE-A (Remote UE) 20 iii then discovers UE-B (UE-to-NW Relay) 30 iii using ProSe Direct Discovery procedures on PC5 interface, for example having moved into the cell in which UE-B (UE-to-NW Relay) 30 iii is located. In the present example, UE-A (Remote UE) 20 iii then derives a shared session key Ks_NAF from its initial bootstrapping procedures and then derives a direct communication ProSe key Ks_UE-B (Ks_UE-to-NW Relay) from Ks_NAF and the UE-B (UE-to-NW Relay) 30 iii identity. This identity is obtained during the discovery procedure. The ProSe key Ks_UE-B (Ks_UE-to-NW Relay) is then available in UE-A (Remote UE) 20 iii for direct communication between UE-A (Remote UE) 20 iii and UE-B (UE-to-Network Relay) 30 iii on the PC5 interface.

UE-A (Remote UE) 20 iii then contacts UE-B (UE-to-NW Relay) via the PC5 interface indicating the B-TID and an identity of the DCE 40Aiii, which in this case is the Home ProSe Function of PLMN A, which is acting as a NAF for the purposes of GBA. UE-A (Remote UE) 20 iii requests UE-B (UE-to-NW Relay) 30 iii to contact the NAF 40Aiii to request the NAF 40Aiii to derive the ProSe key for direct communication from a Ks_NAF key identified by the B-TID and UE-B (UE-to-NW Relay) 30 iii identity. UE-A (Remote UE) 20 iii also requests that the derived ProSe key be provisioned to UE-B (UE-to-NW Relay) 30 iii. UE-A (Remote UE) 20 iii may also provide its identity, for example if this has not already been provided via discovery.

In this Example, the DCE comprises two sub-Elements, the ProSe Function in PLMN A 40Aiii, which is acting as the NAF for GBA bootstrapping, and the ProSe Function in PLMN B 40Biii, which acts as a relay and derives the direct communication key. UE-B (UE-to-Network Relay) 30 iii thus contacts the ProSe Function of its Home PLMN 40Biii with the B-TID and UE-B (UE-to-NW Relay) 30 iii identity. The Home ProSe Function 40Biii then contacts via interface PC6 the NAF 40Aiii identified by UE-A (Remote UE) 20 iii, requesting the session shared key Ks_NAF identified by the B-TID. If the NAF 40Aiii does not have the Ks_NAF key identified by the B-TID already, then the NAF 40Aiii contacts the BSF 50Aiii with the B-TID and retrieves the corresponding Ks_NAF key. The NAF 40Aiii returns Ks_NAF to the Home ProSe Function 40Biii of UE-B (UE-to-Network Relay) 30 iii. The Home ProSe Function 40Biii of UE-B (UE-to-Network Relay) 30 iii derives the ProSe key Ks_UE-B (Ks_UE-to-NW Relay), to be used for direct communication, from the Ks_NAF and UE-B (UE-to-NW Relay) 30 iii identity. The Home ProSe Function 40Biii of UE-B (UE-to-Network Relay) 30 iii provides the derived ProSe key to UE-B (UE-to-NW Relay) 30 iii over a secure link.

The above steps are described in greater detail below with reference to the messaging flow diagram in FIG. 13.

In step 102 iii (message exchanges 1 to 4) UE-A (Remote UE) 20 iii is served by E-UTRAN and initiates a GBA bootstrapping with its BSF 50Aiii according to TS 33.220. When the GBA bootstrapping procedure has taken place successfully then the UE-A (Remote UE) 20 iii and the BSF 50Aiii have established a UE shared key Ks, a B-TID and a key lifetime of the Ks.

Following step 102 iii, UE-A (Remote UE) 20 iii may move outside of E-UTRAN coverage. In message exchange 5, UE-B (UE-to-NW Relay) 30 iii is served by E-UTRAN and initiates E-UTRAN Attach and requests PDN connectivity.

UE-A (Remote UE) 20 iii and UE-B (UE-to-NW Relay) 30 iii then discover each other through Direct Discovery procedures using Direct Discovery Model A or Direct Discovery Model B at message exchange 6. Discovery may be initiated by either UE-A (Remote UE) 20 iii or UE-B (UE-to-NW Relay) 30 iii. In the illustrated example, discovery is initiated by UE-B (UE-to-NW Relay) 30 iii. In step 204 iii, UE-B (UE-to-NW Relay) 30 iii issues a discovery message, which may be a Direct Discovery broadcast according to ProSe Model A or a Direct Discovery request message according to ProSe Model B. The discovery message includes an identity of UE-B (UE-to-NW Relay) 30 iii. UE-A (Remote UE) 20 iii receives the discovery message at step 106 iii.

UE-A (Remote UE 20 iii is therefore in possession of the NAF ID and the identity of UE-B (UE-to-Network Relay) 30 iii and may derive the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) for securing direct communication with UE-B (ProSe-UE-to-Network Relay) 30 iii. This process (message exchange 7) is achieved in steps 134 iii and 136 iii in UE-A (Remote UE) 20 iii. In step 134 iii, UE-A (Remote UE) calculates the shared session key Ks_NAF from Ks and a NAF_ID as follows: Ks_NAF=KDF(Ks, NAF_ID, . . . ), where KDF is a key derivation function having as inputs at least Ks and NAF_ID. Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place. As the NAF is the ProSe Function of PLMN A, which is the Home PLMN of UE-A (Remote UE) 20 iii, the NAF ID is known to UE-A (Remote UE) 20 iii and may not need to be obtained from UE-B (ProSe-UE-to-Network Relay) 30 iii during the discovery procedure.

In step 136 iii, UE-A (Remote UE) 20 iii calculates the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) from Ks_NAF and the UE-B ID (UE-to-NW Relay ID) as follows:

Ks_UE-B(Ks_UE-to-NW_Relay)=KDF(Ks_NAF, UE-B ID (UE-to-NW Relay ID), . . . ),

where KDF is a key derivation function having as inputs at least Ks_NAF and UE-B ID (UE-to-NW Relay ID). Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place.

In the procedure illustrated at message exchange 8, UE-A (Remote UE) 20 iii requests UE-B (UE-to-NW Relay) 30 iii to contact the NAF 40Aiii in order to request the NAF 40Aiii to derive the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay), to be used for direct communication on the PC5 interface. The ProSe key is to be derived from a Ks_NAF identified by a B-TID sent by UE-A (Remote UE).

In step 108 iii, UE-A (Remote UE) 20 ii sends the request to UE-B (UE-to-NW Relay) 30 iii on the PC5 interface. In the illustrated example, the request is sent as part of a Direct Discovery response message according to Model B of ProSe Direct Discovery. The Direct Discovery response message contains the B-TID and the NAF ID and may also contain the UE-A (Remote UE) 20 iii identity. In the illustrated example, the Direct Discovery response message also contains a Message Authentication Code (MAC). The method 100 performed at the UE may thus further comprise a step of generating a MAC using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay). In alternative examples, such as where Direct Discovery according to Model A is used, the request sent at step 112 iii may simply be a request message sent on the PC5 interface in response to a discovery broadcast from UE-B (UE-to-NW Relay) 30 iii.

In message exchange 9, UE-B (ProSe UE-to-Network Relay) 30 iii contacts its own home ProSe Function 40Biii over the interface PC3 by initiating the establishment of a secure link with the ProSe Function 40Biii. This may comprise initiating, for example, a TLS tunnel using pre-shared certificates or with GBA.

In message exchange 10, UE-B (ProSe UE-to-Network Relay) 30 iii requests its Home ProSe Function 40Biii to derive the ProSe key from a Ks_NAF identified by a B-TID, and to provision the derived ProSe key to the UE-B (ProSe UE-to-Network Relay) 30 iii. UE-B (ProSe UE-to-Network Relay) 30 iii sends the message at step 212 iii, including the B-TID received from UE-A (Remote UE) 20 iii and the UE-B identity (UE-to-NW Relay identity). The request may also contain the UE-A (Remote UE) 20 iii identity. This message is received by the Home ProSe Function 40Biii at step 314 iii. In step 316 iii (message exchange 11), the Home ProSe Function 40Biii authorizes the UE-B identity (UE-to-NW Relay identity) by checking a database with a list of authorized identities. This database may be local and supported by the Home ProSe Function 40Biii or may be implemented in a different network server.

If the UE-B identity (UE-to-NW Relay identity) is configured in the database, then the UE-B (UE-to-NW Relay) 30 iii is authorized to request the key corresponding to the B-TID. The Home ProSe Function 40Biii therefore requests the session shared key Ks_NAF in step 318 iii and receives the requested key in step 320 iii. This is achieved by first contacting the NAF 40Aiii over the PC6 interface, requesting the key corresponding to the B-TID. The NAF 40Aiii may authorize the UE-A (Remote UE) 20 iii identity and then contacts the BSF 50Aiii to request the session shared key Ks_NAF, as described in TS 33.220. The NAF receives Ks_NAF from the BSF 50Aiii and sends the session shared key Ks_NAF to the Home ProSe Function 40Biii of UE-B (UE-to-NW Relay) 30 iii.

In step 322 iii (message exchange 12) the Home ProSe Function 40Biii of UE-B (UE-to-NW Relay) 30 iii calculates the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) to be provisioned to UE-B (UE-to-NW Relay) 30 iii. This is the same ProSe key as was derived by UE-A (Remote UE) 20 iii for direct communication on the PC5 interface between UE-A (Remote UE) 20 iii and UE-B (UE-to-NW Relay) 30 iii.

The Home ProSe Function 40Biii of UE-B (UE-to-NW Relay) 30 iii calculates the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) from Ks_NAF and UE-B ID (ProSe UE-to-Network Relay ID) as follows:

Ks_UE-B(Ks_UE-to-NW_Relay)=KDF(Ks_NAF, UE-B ID (UE-to-NW Relay ID), . . . ).

As discussed above, KDF is a key derivation function having as inputs at least Ks_NAF and UE-B ID (UE-to-NW Relay ID). Additional inputs may be included, and processing of the inputs before inputting to the KDF may take place. The Home ProSe Function 40Biii also generates a ProSe key identity and a ProSe key lifetime to be associated with the newly derived ProSe key Ks_UE-B (Ks_UE-to-NW_Relay).

In message exchange 13, the Home ProSe Function 40Biii of UE-B (UE-to-NW Relay) 30 iii sends or provisions the derived key Ks_UE-B (Ks_UE-to-NW_Relay), ProSe key identity and a ProSe key lifetime to UE-B (UE-to-NW Relay) 30 iii. The Home ProSe Function 40Biii of UE-B (UE-to-NW Relay) sends a message containing the ProSe key in step 324 iii, which message is received by UE-B (UE-to-NW Relay) 30 iii in step 226 iii.

In step 228 iii, UE-B (UE-to-NW Relay) 30 iii checks the MAC received from UE-A (Remote UE) 20 iii in step 210 iii using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) received from the Home ProSe Function 40Biii of UE-B (UE-to-NW Relay). If the check is successful, then UE-B (UE-to-NW Relay) 30 iii responds to UE-A (Remote UE) 20 iii that the check was successful and protects the response with a MAC using Ks_UE-B (Ks_UE-to-NW_Relay) in message exchange 14. The response message is sent by UE-B (UE-to-NW Relay) 30 iii in step 234 iii and received by UE-A (Remote UE) at step 136 iii. The response may also include the ProSe key identity and a ProSe key lifetime.

In step 138 iii, UE-A (Remote UE) 20 iii checks the MAC received in step 136 iii using the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay). If the check is successful, then UE-A (Remote UE) 20 iii knows that UE-B (UE-to-NW Relay) 30 iii shares the same ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) as UE-A (Remote UE) 20 iii. UE-A (Remote UE) 20 iii can now use the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) for direct communication on the PC5 interface with UE-B (UE-to-NW Relay) 30 iii.

In message exchange 15, UE-A (Remote UE) 20 iii confirms to UE-B (UE-to-NW Relay) 30 iii, that the check of the MAC was successful and that ProSe Direct Communication on PC5 interface between UE-A (Remote UE) 20 iii and UE-B (UE-to-NW Relay) 30 iii can now take place using the derived ProSe key Ks_UE-B (Ks_UE-to-NW_Relay). In some examples, a further derivation step may be applied to the ProSe key Ks_UE-B (Ks_UE-to-NW_Relay) before it is used. UE-A (Remote UE) 20 iii protects the confirmation with a MAC using either Ks_UE-B (Ks_UE-to-NW_Relay) or a key used for direct discovery procedure. The confirmation message is sent by UE-A (Remote UE) 20 iii in step 140 iii and received at UE-B (UE-to-NW Relay) 30 iii in step 242 iii.

As in the previous examples, mutual authentication may be included in the methods illustrated by Example iii. UE-A (Remote UE) 20 iii and UE-B (UE-to-NW Relay) 30 iii may generate nonces for mutual authentication: UE-A (Remote UE) 20 iii generates nonce-UE-A and UE-B (UE-to-NW Relay) 30 iii generates nonce-UE-B. A nonce may for example be a sequence number, a random value or a timestamp. Nonces may be exchanged in various messages of the above described example procedure. In one example, UE-A (Remote UE) 20 iii sends nonce-UE-A to UE-B (UE-to-NW Relay) 30 iii with the request to obtain a direct communication key sent in step 108 iii (message exchange 8). UE-B (UE-to-NW Relay) 30 iii takes nonce-UE-A as an input to its calculation of a MAC at step 228 iii, which MAC is sent to UE-A (Remote UE) 20 iii in step 230 iii. When UE-A (Remote UE) 20 iii verifies the MAC, this in practice means that UE-A (Remote UE) 20 iii authenticates UE-B (UE-to-NW Relay). An equivalent process allows authentication in the other direction. UE-B (UE-to-NW Relay) 30 iii sends nonce-UE-B to UE-A (Remote UE) 20 iii in step 230 iii (message exchange 14). UE-A (Remote UE) uses nonce-UE-B as an input to its MAC calculation, which MAC is sent to the UE-B (UE-to-NW Relay) in step 140 iii (message exchange 15). When UE-B (UE-to-NW Relay) 30 iii verifies the MAC, this in practice means that UE-B (UE-to-NW Relay) authenticates UE-A (Remote UE) 20 iii.

The methods of the present invention, as illustrated by the above examples, may be conducted in a UE, a device which may be a UE, a UE-to-Network Relay, or may be a network node, or a Direct Communication Element (DCE) such as a ProSe Function or a KMS. The methods may be conducted on receipt of suitable computer readable instructions, which may be embodied within a computer program running on the UE, device or DCE. FIGS. 14 to 16 illustrate first examples of a UE, device and DCE which may execute the methods of the present invention, for example on receipt of suitable instructions from a computer program. Referring to FIGS. 14 to 16, each of the UE 400, device 500 and DCE 600 comprises a processor 402, 502, 602 and a memory 404, 504, 604. The memory 404, 504, 604 contains instructions executable by the processor 402, 502, 602 such that the UE 400 is operative to carry out the method 100, the device 500 is operative to carry out the method 200 and the DCE 600 is operative to carry out the method 300.

FIG. 17 illustrates functional units in another embodiment of UE 700A which may execute the method 100, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 17 are software implemented functional units, and may be realised in any appropriate combination of software modules.

Referring to FIG. 17, the UE 700A comprises GBA means 702A for establishing a UE shared key with a BSF using a GBA procedure and for receiving from the BSF a transaction identifier associated with the UE shared key. The UE 700A also comprises discovery means 708A for discovering a device through a discovery procedure after receipt of the transaction identifier. The UE 700A also comprises communication means 706A for sending the transaction identifier and a Direct Communication Element identifier to the device and for requesting the device to obtain the direct communication key. The UE 700A also comprises key means 704A for deriving a session shared key from at least the UE shared key and the Direct Communication Element identifier, and for deriving a direct communication key from at least the session shared key and an identifier of the device.

The communication means 706A may also comprise means for receiving a discovery message from the device and for passing the message to the discovery means 708A, wherein the discovery message includes the identifier of the device.

The communication means 706A may further comprise means for sending the transaction identifier and the Direct Communication Element identifier to the device, and for requesting the device to obtain the direct communication key by sending a discovery response message responding to the received discovery message and assembled by the discovery means 708A.

The communication means 706a may further comprise means for receiving a first confirmation message from the device indicating that the device has obtained the direct communication key, and for receiving a MAC with the first confirmation message, wherein the MAC is generated using the direct communication key. The key means 704A may further comprise means for checking the MAC using the direct communication key, and, if the check is successful, the communication means 706A may comprise means for sending a second confirmation message to the device.

In one example, the GBA means 702A, key means 704A, communication means 706A and discovery means 708A may be implemented with help from a computer program which, when run on a processor, causes the GBA means 702A, key means 704A, communication means 706A and discovery means 708A to cooperate to carry out examples of the method 100 as described above.

FIG. 18 illustrates functional units in another embodiment of device 800A which may execute the method 200 of the present invention, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 18 are software implemented functional units, and may be realised in any appropriate combination of software modules.

Referring to FIG. 18, the device 800A comprises discovery means 806A for discovering the UE through a discovery procedure, and communication means 802A for receiving from the UE a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key, and for sending to the Direct Communication Element identified by the Direct Communication Element identifier the transaction identifier and an identifier of the device, and for requesting the Direct Communication Element to provide the device with the direct communication key. The communication means 802A also comprise means for receiving the direct communication key from the Direct Communication Element. The device 800A also comprises key means 804A for storing the direct communication key.

The communication means 804A may further comprise means for sending a discovery message to the UE, wherein the discovery message includes the identifier of the device and is assembled by the discovery means 806A. The discovery message may further include the Direct Communication Element identifier.

The key means 804A may further comprise means for generating a MAC using the direct communication key received from the Direct Communication Element. The communication means 802A may further comprise means for sending the MAC with a first confirmation message.

The device 800A may be at least one of a UE or a UE-to-Network Relay. In some examples, the communication means 802A, key means 804A and discovery means 806A may be implemented with help from a computer program which, when run on a processor, causes the communication means 802A, key means 804A and discovery means 806A to cooperate to carry out examples of the method 200 as described above.

FIG. 19 illustrates functional units in another embodiment of DCE 900A which may execute the method 300 of the present invention, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 19 are software implemented functional units, and may be realised in any appropriate combination of software modules.

Referring to FIG. 19, the DCE 900A comprises communication means 902A for receiving from a device a transaction identifier, a device identifier and a request to provide a direct communication key to the device, for sending the transaction identifier to a BSF corresponding to the transaction identifier and for receiving a session shared key from the BSF. The DCE 900A further comprises Key means 904A for deriving a UE direct communication key from the session shared key and at least the device identifier. The communication means 902A further comprise means for sending the direct communication key to the device.

The DCE 900A may comprise at least one of a ProSe Function or a ProSe KMS.

The DCE 900A may further comprise authorising means 906A for checking that the device is authorised to establish direct communication with the UE and/or that the UE is authorised to establish direct communication with the device.

The DCE 900A may comprise a first sub-Element 908A in a first communication network and a second sub-Element 910A in a second communication network. The first and second sub elements may each comprise communication means 902A, 912A, key means 904A, 914A and authorising means 906A, 916A.

The communication means 902A or 912A in one of the first or second sub-Elements 908A, 910A may comprise means for sending to and receiving from at least one of the BSF or the device by sending to and receiving from the communication unit 902A or 912A in the other of the first or second sub-Elements 908A, 910A.

In some examples, the communication means 902A, 912A, key means 904A, 914A and authorising means 906A, 916A may be implemented with help from a computer program which, when run on a processor, causes the communication means 902A, 912A, key means 904A, 914A and authorising means 906A, 916A to cooperate to carry out examples of the method 300 as described above.

FIG. 20 illustrates functional units in another embodiment of UE 700B which may execute the method 100, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 20 are hardware implemented functional units, and may be realised in any appropriate combination of hardware elements.

Referring to FIG. 20, the UE 700B comprises a GBA unit 702B configured to establish a UE shared key with a BSF using a GBA procedure and to receive from the BSF a transaction identifier associated with the UE shared key, and a discovery unit 704B configured to discover a device through a discovery procedure after receipt of the transaction identifier. The UE 700B also comprises a communication unit 708B configured to send the transaction identifier and a Direct Communication Element identifier to the device and to request the device to obtain the direct communication key. The UE 700B also comprises a key unit 706B configured to derive a session shared key from at least the UE shared key and the Direct Communication Element identifier and to derive a direct communication key from at least the session shared key and an identifier of the device.

The communication unit 708B may be configured to receive a discovery message from the device and to pass the message to the discovery unit 704B, wherein the discovery message includes the identifier of the device.

The communication unit 704B may further be configured to send the transaction identifier and the Direct Communication Element identifier to the device, and to request the device to obtain the direct communication key by sending a discovery response message responding to the received discovery message and assembled by the discovery unit 704B.

The communication unit 708B may be further configured to receive a first confirmation message from the device indicating that the device has obtained the direct communication key. The communication unit 706B may be configured to receive a MAC with the first confirmation message, wherein the MAC is generated using the direct communication key. The key unit may be configured to check the MAC using the direct communication key, and, if the check is successful, the communication unit 708B may be configured to send a second confirmation message to the device. The key unit 706B may further be configured to generate a MAC using the direct communication key and the communication unit 708B may be configured to send the MAC to the device with second confirmation message.

FIG. 21 illustrates functional units in another embodiment of device 800B which may execute the method 200 of the present invention, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 21 are hardware implemented functional units, and may be realised in any appropriate combination of hardware elements.

Referring to FIG. 21, the device 800B comprises a discovery unit 802B configured to discover a UE through a discovery procedure. The device also comprises a communication unit 804B configured to receive from the UE a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key, and to send to the Direct Communication Element identified by the Direct Communication Element identifier the transaction identifier and an identifier of the device, and to request the Direct Communication Element to provide the device with the direct communication key. The communication unit 804B is also configured to receive the direct communication key from the Direct Communication Element and store it in a key unit 806B.

The communication unit 804B may be further configured to send a discovery message to the UE, wherein the discovery message includes the identifier of the device and is assembled by the discovery unit 802B. The discovery message may further include the Direct Communication Element identifier.

The communication unit 804B may be further configured to send a first confirmation message to the UE indicating that the device has obtained the direct communication key. The communication unit 804B may be further configured to receive a second confirmation message from the UE.

The key unit 806B may be configured to generate a MAC using the direct communication key received from the Direct Communication Element. The communication unit 804B may be configured to send the confirmation MAC with the first confirmation message.

The device 800B may be at least one of a UE, a UE-to-Network Relay, or a network node.

FIG. 22 illustrates functional units in another embodiment of DCE 900B which may execute the method 300 of the present invention, for example according to computer readable instructions received from a computer program. It will be understood that the units illustrated in FIG. 22 are hardware implemented functional units, and may be realised in any appropriate combination of hardware elements.

Referring to FIG. 22, the DCE 900B comprises a communication unit 902B configured to receive from a device a transaction identifier, a device identifier and a request to provide a direct communication key to the device, to send the transaction identifier to a BSF corresponding to the transaction identifier and to receive a session shared key from the BSF. The DCE 900B further comprises a Key unit 904B configured to derive the direct communication key from the session shared key and at least the device identifier. The communication unit 902B is further configured to send the direct communication key to the device.

The DCE 900B may comprise at least one of a ProSe Function or a ProSe KMS.

The DCE 900B may further comprise an authorising unit 906B configured to check that the device is authorised to establish direct communication with the UE and/or that the UE is authorised to establish direct communication with the device.

The DCE 900B may comprise a first sub-Element 908 in a first communication network and a second sub-Element 910B in a second communication network. The first and second sub elements may each comprise a communication unit 902B, 912B, a key unit 904B, 914B and an authorising unit 906B, 916B.

The communication unit 902B or 912B in one of the first or second sub-Elements 908, 910 may be configured to send to and receive from at least one of the BSF or the device by sending to and receiving from the communication unit 902B or 912B in the other of the first or second sub-Elements 908B, 910B.

Aspects of the present invention thus provide methods, apparatus, computer programs and a system enabling the establishment of a key for direct communication between a UE and a device. The key is established without requiring pre-configuration in the UE and device. Additionally, the key is established using initial GBA bootstrapping procedures and yet the UE retains the flexibility to move outside of network coverage before discovering the device with which the shared key will be used and without requiring any additional bootstrapping procedure to be conducted by the other device.

The methods of the present invention may be implemented in hardware, or as software modules running on one or more processors. The methods may also be carried out according to the instructions of a computer program, and the present invention also provides a computer readable medium having stored thereon a program for carrying out any of the methods described herein. A computer program embodying the invention may be stored on a computer-readable medium, or it could, for example, be in the form of a signal such as a downloadable data signal provided from an Internet website, or it could be in any other form.

It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. The word “comprising” does not exclude the presence of elements or steps other than those listed in a claim, “a” or “an” does not exclude a plurality, and a single processor or other unit may fulfil the functions of several units recited in the claims. Any reference signs in the claims shall not be construed so as to limit their scope. 

1. A method performed by a User Equipment (UE) for obtaining a key for direct communication with a device over a Proximity Services (ProSe) interface, wherein the UE is comprised within a first communication network and the device is comprised within a second communication network, the method comprising: establishing a UE shared key with a Bootstrapping Server Function (BSF) using a Generic Bootstrapping Architecture (GBA) procedure, and receiving from the BSF a transaction identifier associated with the UE shared key; discovering the device through a discovery procedure after receipt of the transaction identifier; sending to the device the transaction identifier and a Direct Communication Element identifier of at least one Direct Communication Element, which comprises at least one of a ProSe Function and a ProSe Key Management Server, and requesting the device to obtain the direct communication key; deriving a session shared key from at least the UE shared key and the Direct Communication Element identifier; and deriving a direct communication key from at least the session shared key and an identifier of the device.
 2. The method of claim 1, wherein at least one of the transaction identifier, the Direct Communication Element identifier or the request to obtain the direct communication key is comprised within a discovery procedure message.
 3. The method of claim 1, further comprising receiving a discovery message from the device, wherein the discovery message includes the identifier of the device.
 4. The method of claim 1, wherein sending the transaction identifier and the Direct Communication Element identifier to the device, and requesting the device to obtain the direct communication key comprises sending a discovery response message responding to the received discovery message.
 5. The method of claim 1, further comprising receiving a first confirmation message from the device indicating that the device has obtained the direct communication key.
 6. A method, performed by a device, for obtaining a key for direct communication with a User Equipment (UE) over a Proximity Services (ProSe) interface, wherein the UE is comprised within a first communication network and the device is comprised within a second communication network, the method comprising: discovering the UE through a discovery procedure; receiving from the UE a transaction identifier, a Direct Communication Element identifier of at least one Direct Communication Element, which comprises at least one of a ProSe Function and a ProSe Key Management Server, and a request to obtain a direct communication key; sending to the Direct Communication Element identified by the Direct Communication Element identifier the transaction identifier and an identifier of the device, and requesting the Direct Communication Element to provide the device with the direct communication key; and receiving the direct communication key from the Direct Communication Element.
 7. The method of claim 6, further comprising sending a discovery message to the UE, wherein the discovery message includes the identifier of the device.
 8. The method of claim 6, wherein receiving from the UE device a transaction identifier, a Direct Communication Element identifier and a request to obtain a direct communication key comprises receiving a discovery response message responding to the sent discovery message.
 9. The method of claim 6, further comprising sending a first confirmation message to the UE indicating that the device has obtained the direct communication key.
 10. The method of claim 6, wherein the device comprises at least one of: a UE, and a UE-to-Network Relay.
 11. The method of claim 6, wherein the Direct Communication Element comprises a first sub-Element in the first communication network and a second sub-Element in the second communication network.
 12. A method, performed by a Direct Communication Element, for establishing a key for direct communication over an interface between a User Equipment (UE) and a device, the method comprising: receiving from the device a transaction identifier, a device identifier and a request to provide a direct communication key to the device; sending the transaction identifier to a Bootstrapping Server Function (BSF) corresponding to the transaction identifier; receiving a session shared key from the BSF; deriving the direct communication key from the session shared key and at least the device identifier; and sending the direct communication key to the device, wherein the UE is comprised within a home Public Land Mobile Network (PLMN) of the UE, the device is comprised within a home PLMN of the device, the interface comprises a Proximity Services (ProSe) interface, and the Direct Communication Element comprises: i) a first sub-Element, wherein the first sub-Element is one of: a) a ProSe Function in the home PLMN of the UE and b) a ProSe Key Management Server in the home PLMN of the UE, and ii) a second sub-Element, wherein the second sub-Element is one of: a) a ProSe Function in the home PLMN of the device and b) a ProSe Key Management Server in the home PLMN of the device.
 13. The method of claim 12, further comprising checking that the device is authorized to establish direct communication with the UE.
 14. A system for securing direct communication between a User Equipment (UE) and a device over an interface, the system comprising a UE, a device and a Direct Communication Element; wherein the UE is configured to establish a UE shared key with a Bootstrapping Server Function (BSF) using a Generic Bootstrapping Architecture (GBA) procedure; to discover the device through a discovery procedure after establishing the UE shared key; and to derive a direct communication key from at least the UE shared key; wherein the device is configured to receive a transaction identifier associated with the UE shared key from the UE; to send the transaction identifier to the Direct Communication Element; and to receive the direct communication key from the Direct Communication Element; and wherein the Direct Communication Element is configured to receive the transaction identifier from the device, to obtain a shared session key from the BSF; to derive the direct communication key; and to send the direct communication key to the device.
 15. The system of claim 14, wherein the UE is configured to derive the direct communication key by deriving the shared session key from at least the UE shared key and a Direct Communication Element identifier, and by deriving the direct communication key from at least the shared session key and a device identifier.
 16. The system of claim 14, wherein the Direct Communication Element is configured to derive the direct communication key from at least the shared session key and a device identifier.
 17. A User Equipment (UE) configured for obtaining a key for direct communication with a device over an interface, the UE comprising a processor and a memory, the memory containing instructions executable by the processor, such that the UE is operable to carry out a method according to claim
 1. 18. A device configured for obtaining a key for direct communication with a User Equipment (UE) over an interface, the device comprising a processor and a memory, the memory containing instructions executable by the processor, such that the device is operable to carry out a method according to claim
 10. 19. A Direct Communication Element configured for establishing a key for direct communication over an interface between a User Equipment (UE) and a device, the Direct Communication Element comprising a processor and a memory, the memory containing instructions executable by the processor, such that the Direct Communication Element is operable to carry out a method according to claim
 19. 20. A non-transitory computer readable medium having instructions stored therein, which when executed by a processor causes the processor to execute the method according to claim
 1. 